Electrosurgical ablation apparatus and method

ABSTRACT

The present invention relates to the field of electrosurgery, and more particularly to a system that produces a focused plasma for tissue ablation. The system includes a probe and a remote source of a conductive liquid media for providing a flow through the probe that functions as an electrode. A pressurized flow of the liquid media passes through a first larger diameter flow channel in the probe to then increases in velocity as it passes through a smaller diameter flow restriction channel in a working end surface. The flow restriction of the liquid electrode through the flow restriction channel when coupled with high frequency voltage causes instantaneous ignition of a plasma within media flow media within the flow restriction channel. The working end surface thus carries a plasma that when proximate to tissue will cause a controlled, focused ablation.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit from Provisional U.S. Patent Application Ser. No. 60/756,138 filed Jan. 3, 2006 having the same title. This application is a Continuation-In-Part of U.S. patent application Ser. No. 11/090,706 filed Mar. 24, 2005 now U.S. Pat. No. 7,744,595 titled VOLTAGE THRESHOLD ABLATION APPARATUS. All of the above applications are incorporated herein by this reference and made a part of this specification.

FIELD OF THE INVENTION

The present invention relates to the field of electrosurgery, and more particularly to systems and methods for ablating, cauterizing and/or coagulating body tissue using an intense plasma created by an electrode of a liquid media coupled to radio frequency energy source.

BACKGROUND OF THE INVENTION

Radio frequency ablation is a method by which body tissue is destroyed by passing radio frequency current into the tissue. Some RF ablation procedures rely on application of high currents and low voltages to the body tissue, resulting in resistive heating of the tissue which ultimately destroys the tissue. These techniques suffer from the drawback that the heat generated at the tissue can penetrate deeply, making the depth of ablation difficult to predict and control. This procedure is thus disadvantageous in applications in which only a fine layer of tissue is to be ablated, or in areas of the body such as the heart or near the spinal cord where resistive heating can result in undesirable collateral damage to critical tissues and/or organs.

It is thus desirable to ablate such sensitive areas using high voltages and low currents, thus minimizing the amount of current applied to body tissue.

SUMMARY OF THE INVENTION

The present invention is a method and apparatus for treating or ablating tissue with an electrosurgical system that produces a focused plasma. The system includes an electrosurgical system including an RF generator and an elongated probe with a working end fabricated of a non-conductive ceramic body. The system further includes a remote source of a conductive liquid media functioning as an electrode wherein a pressurized flow of the liquid media passes through a first flow channel in the probe to then pass through at least one flow restriction channel in the working end. The source of conductive liquid media is provided by any suitable form of pump capable of providing a pressure ranging from about 1 psi to 1,000 psi.

In use, the invention comprises providing a flow of a liquid electrode through a probe and the at least one flow restriction channel when the working end is adjacent to or in contact with targeted tissue, and applying high frequency voltage to the liquid electrode flow wherein the increased resistance of the media flow causes instantaneous ignition of a plasma within the flow restriction channel for ablation of tissue. In another method, the step of restricting the flow of conductive fluid includes restricting the flow by contacting at least one opening in the working surface with targeted tissue.

In another embodiment, the probe of the present invention includes the steps of using the RF generator to apply a voltage across the spark gap switch, the spark gap switch causing conduction of current from the RF generator to the flow of conductive media once the voltage across the spark gap reaches the threshold voltage.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional side elevation view of a first embodiment of an ablation device utilizing principles of the present invention.

FIG. 2 is an end view showing the distal end of the device of FIG. 1.

FIG. 3 is a graphical representation of voltage output from an RF generator over time.

FIG. 4A is a graphical representation of voltage potential across a body tissue load, from an ablation device utilizing voltage threshold ablation techniques as described herein.

FIG. 4B is a graphical representation of voltage potential across a body tissue load, from an ablation device utilizing voltage threshold ablation techniques as described herein and further utilizing techniques described herein for decreasing the slope of the trailing edge of the waveform.

FIGS. 5A through 5D are a series of cross-sectional side elevation views of the ablation device of FIG. 1, schematically illustrating use of the device to ablate tissue.

FIG. 6A is a cross-sectional side view of a second embodiment of an ablation device utilizing principles of the present invention.

FIG. 6B is an end view showing the distal end of the device of FIG. 6A.

FIGS. 7A and 7B are cross-sectional side elevation view of a third embodiment of an ablation device utilizing principles of the present invention. In FIG. 7A, the device is shown in a contracted position and in FIG. 7B the device is shown in an expanded position.

FIG. 8A is a perspective view of a fourth embodiment of an ablation device utilizing principles of the present invention.

FIG. 8B is a cross-sectional side elevation view of the ablation device of FIG. 8A.

FIG. 9A is a perspective view of a fifth embodiment of an ablation device utilizing principles of the present invention.

FIG. 9B is a cross-sectional side elevation view of the ablation device of FIG. 9A.

FIG. 10 is a cross-sectional side elevation view of a sixth ablation device utilizing principles of the present invention.

FIG. 11A is a perspective view of a seventh embodiment of an ablation device utilizing principles of the present invention.

FIG. 11B is a cross-sectional side elevation view of the ablation device of FIG. 11A.

FIG. 11C is a cross-sectional end view of the ablation device of FIG. 11A.

FIG. 12A is a perspective view of an eighth embodiment of an ablation device utilizing principles of the present invention.

FIG. 12B is a cross-sectional side elevation view of the ablation device of FIG. 12A.

FIG. 13A is a cross-sectional side elevation view of a ninth embodiment of an ablation device utilizing principles of the present invention.

FIG. 13B is a cross-sectional end view of the ablation device of FIG. 13A, taken along the plane designated 13B-13B in FIG. 13A.

FIG. 14A is a cross-sectional side elevation view of a tenth embodiment of an ablation device utilizing principles of the present invention.

FIG. 14B is a front end view of the grid utilized in the embodiment of FIG. 14A.

FIG. 15A is a cross-sectional side elevation view of an eleventh embodiment.

FIG. 15B is a cross-sectional end view of the eleventh embodiment taken along the plane designated 15B-15B in FIG. 15A.

FIG. 15C is a schematic illustration of a variation of the eleventh embodiment, in which the mixture of gases used in the reservoir may be adjusted so as to change the threshold voltage.

FIGS. 16A-16D are a series of drawings illustrating use of the eleventh embodiment.

FIG. 17 is a series of plots graphically illustrating the impact of argon flow on the ablation device output at the body tissue/fluid load.

FIG. 18 is a series of plots graphically illustrating the impact of electrode spacing on the ablation device output at the body tissue/fluid load.

FIG. 19 is a schematic illustration of a twelfth embodiment of a system utilizing principles of the present invention, in which a spark gap spacing may be selected so as to pre-select a threshold voltage.

FIG. 20 is a perspective view of a hand-held probe corresponding to the invention with a voltage threshold mechanism at the interior of a microporous ceramic working surface.

FIG. 21 is a sectional view of the working end of the probe of FIG. 20.

FIG. 22 is a greatly enlarged cut-away schematic view of the voltage threshold mechanism and microporous ceramic working surface of FIG. 21.

FIG. 23 is a cut-away schematic view of an alternative voltage threshold mechanism with multiple spark gaps dimensions.

FIG. 24 is a cut-away schematic view of an alternative voltage threshold mechanism with a microporous electrode.

FIG. 25 is a sectional view of an alternative needle-like probe with a voltage threshold mechanism at it interior.

FIG. 26 is a sectional view of an alternative probe with a voltage threshold mechanism at it interior together with an exterior electrode to allow functioning in a bi-polar manner.

FIG. 27A is a sectional view of an alternative probe that includes a liquid electrode with a flow restrictor system for creating a plasma for tissue ablation.

FIG. 27B is another view of the probe of FIG. 27A illustrating a method of use wherein the electrode is converted into a plasma for tissue ablation.

FIG. 28 is a sectional view of an alternative probe with a liquid electrode system as in FIG. 27A for tissue ablation.

FIG. 29 is a sectional view of an alternative probe with a liquid electrode system for tissue ablation.

FIG. 30 is a sectional view of an alternative probe with a liquid electrode system for tissue ablation.

FIG. 31 is a section view of an alternative probe with a fluid/gas spark gap switch.

DETAILED DESCRIPTION OF THE INVENTION

Several embodiments of ablation systems useful for practicing a voltage threshold ablation method utilizing principles of the present invention are shown in the drawings. Generally speaking, each of these systems utilizes a switching means that prevents current flow into the body until the voltage across the switching means reaches a predetermined threshold potential. By preventing current flow to tissue until a high threshold voltage is reached, the invention minimizes collateral tissue damage that can occur when a large amount of current is applied to the tissue. The switching means may take a variety of forms, including but not limited to an encapsulated or circulated volume of argon or other fluid/gas that will only conduct ablation energy from an intermediate electrode to an ablation electrode once it has been transformed to a plasma by being raised to a threshold voltage.

The embodiments described herein utilize a spark gap switch for preventing conduction of energy to the tissue until the voltage potential applied by the RF generator reaches a threshold voltage. In a preferred form of the apparatus, the spark gap switch includes a volume of fluid/gas to conduct ablation energy across the spark gap, typically from an intermediate electrode to an ablation electrode. The fluid/gas used for this purpose is one that will not conduct until it has been transformed to conductive plasma by having been raised to a threshold voltage. The threshold voltage of the fluid/gas will vary with variations in a number of conditions, including fluid/gas pressure, distance across the spark gap (e.g. between an electrode on one side of the spark gap and an electrode on the other side of the spark gap), and with the rate at which the fluid/gas flows within the spark gap—if flowing fluid/gas is used. As will be seen in some of the embodiments, the threshold voltage may be adjusted in some embodiments by changing any or all of these conditions.

A first embodiment of an ablation device 10 utilizing principles of the present invention is shown in FIGS. 1-2. Device 10 includes a housing 12 formed of an insulating material such as glass, ceramic, siliciumoxid, PTFE or other material having a high melting temperature. At the distal end 13 of the housing 12 is a sealed reservoir 20. An internal electrode 22 is disposed within the sealed reservoir 20. Electrode 22 is electrically coupled to a conductor 24 that extends through the housing body. Conductor 24 is coupled to an RF generator 28 which may be a conventional RF generator used for medical ablation, such as the Model Force 2 RF Generator manufactured by Valley Lab. A return electrode 30 is disposed on the exterior surface of the housing 12 and is also electrically coupled to RF generator 28.

A plurality of ablation electrodes 32 a-32 c are located on the distal end of the housing 12. Ablation electrodes 32 a-32 c may be formed of tungsten or any conductive material which performs well when exposed to high temperatures. In an alternative embodiment, there may be only one ablation electrode 32, or a different electrode configuration. A portion of each ablation electrode 32 a-32 c is exposed to the interior of reservoir 20. Electrodes 22 and 32 a-32 c, and corresponding electrodes in alternate embodiments, may also be referred to herein as spark gap electrodes.

FIGS. 5A through 5D illustrate the method of using the embodiment of FIG. 1. Referring to FIG. 5A, prior to use the reservoir 20 is filled with a fluid or gas. Preferably, an inert gas such as argon gas or a similar gas such as Neon, Xenon, or Helium is utilized to prevent corrosion of the electrodes, although other fluids/gases could be utilized so long as the electrodes and other components were appropriately protected from corrosion. For convenience only, the embodiments utilizing such a fluid/gas will be described as being used with the preferred gas, which is argon.

It should be noted that while the method of FIGS. 5A-5D is most preferably practiced with a sealed volume of gas within the reservoir 20, a circulating flow of gas using a system of lumens in the housing body may alternatively be used. A system utilizing a circulating gas flow is described in connection with FIGS. 15A-15B.

The distal end of the device 10 is placed against body tissue to be ablated, such that some of the electrodes 32 a, 32 b contact the tissue T. In most instances, others of the electrodes 32 c are disposed within body fluids F. The RF generator 28 (FIG. 1) is powered on and gradually builds-up the voltage potential between electrode 22 and electrodes 32 a-32 c.

Despite the voltage potential between the internal electrode 22 and ablation electrodes 32 a-32 c, there initially is no conduction of current between them. This is because the argon gas will not conduct current when it is in a gas phase. In order to conduct, high voltages must be applied through the argon gas to create a spark to ionize the argon and bring it into the conductive plasma phase. Later in this description these voltages may also be referred to as “initiating voltages” since they are the voltages at which conduction is initiated.

The threshold voltage at which the argon will begin to immediately conduct is dependent on the pressure of the argon gas and the distance between electrode 22 and surface electrodes 32 a-32 c.

Assume P1 is the initial pressure of the argon gas within reservoir 20. If, at pressure P1, a voltage of V1 is required to ignite plasma within the argon gas, then a voltage of V>V1 must be applied to electrode 22 to ignite the plasma and to thus begin conduction of current from electrode 22 to ablation electrodes 32 a-32 c.

Thus, no conduction to electrodes 32 a-32 c (and thus into the tissue) will occur until the voltage potential between electrode 22 and ablation electrodes 32 a-32 c reaches voltage V. Since no current flows into the tissue during the time when the RF generator is increasing its output voltage towards the voltage threshold, there is minimal resistive heating of the electrodes 32 a-32 c and body tissue. Thus, this method relies on the threshold voltage of the argon (i.e. the voltage at which a plasma is ignited) to prevent overheating of the ablation electrodes 32 a, 32 b and to thus prevent tissue from sticking to the electrodes.

The voltage applied by the RF generator to electrode 22 cycles between +V and −V throughout the ablation procedure. However, as the process continues, the temperature of the tip of the device begins to increase, causing the temperature within the reservoir and thus the pressure of the argon to increase. As the gas pressure increases, the voltage needed to ignite the plasma also increases. Eventually, increases in temperature and thus pressure will cause the voltage threshold needed to ignite the plasma to increase above V. When this occurs, flow of current to the ablation electrodes will stop (FIG. 5D) until the argon temperature and pressure decrease to a point where the voltage required for plasma ignition is at or below V. Initial gas pressure P1 and the voltage V are thus selected such that current flow will terminate in this manner when the electrode temperature is reaching a point at which tissue will stick to the electrodes and/or char the tissue. This allows the tip temperature of the device to be controlled by selecting the initial gas pressure and the maximum treatment voltage.

The effect of utilizing a minimum voltage limit on the potential applied to the tissue is illustrated graphically in FIGS. 3 and 4A. FIG. 3 shows RF generator voltage output V_(RF) over time, and FIG. 4A shows the ablation potential V_(A) between internal electrode 22 and body tissue. As can be seen, V_(A) remains at 0 V until the RF generator output V_(RF) reaches the device's voltage threshold V_(T), at which time V_(A) rises immediately to the threshold voltage level. Ablation voltage V_(A) remains approximately equivalent to the RF generator output until the RF generator output reaches 0 V. V_(A) remains at 0 V until the negative half-cycle of the RF generator output falls below (−V_(T)), at which time the potential between electrode 22 and the tissue drops immediately to (−V_(T)), and so on. Because there is no conduction to the tissue during the time that the RF generator output is approaching the voltage threshold, there is little conduction to the tissue during low voltage (and high current) phases of the RF generator output. This minimizes collateral tissue damages that would otherwise be caused by resistive heating.

It is further desirable to eliminate the sinusoidal trailing end of the waveform as an additional means of preventing application of low voltage/high current to the tissue and thus eliminating collateral tissue damage. Additional features are described below with respect FIGS. 14A-18. These additional features allow this trailing edge to be clipped and thus produce a waveform measured at the electrode/tissue interface approximating that shown in FIG. 4B.

Another phenomenon occurs between the electrodes 32 a-32 c and the tissue, which further helps to keep the electrodes sufficiently cool as to avoid sticking. This phenomenon is best described with reference to FIGS. 5A through 5D. As mentioned, in most cases some of the electrodes such as electrode 32 c will be in contact with body fluid while others (e.g. 32 a-32 b) are in contact with tissue. Since the impedance of body fluid F is low relative to the impedance of tissue T, current will initially flow through the plasma to electrode 32 c and into the body fluid to return electrode 30, rather than flowing to the electrodes 32, 32 b that contact tissue T. This plasma conduction is represented by an arrow in FIG. 5A.

Resistive heating of electrode 32 c causes the temperature of body fluid F to increase. Eventually, the body fluid F reaches a boiling phase and a resistive gas/steam bubble G will form at electrode 32 c. Steam bubble G increases the distance between electrode 22 and body fluid F from distance D1 to distance D2 as shown in FIG. 5B. The voltage at which the argon will sustain conductive plasma is dependent in part on the distance between electrode 22 and the body fluid F. If the potential between electrode 22 and body fluid F is sufficient to maintain a plasma in the argon even after the bubble G has expanded, energy will continue to conduct through the argon to electrode 32 c, and sparking will occur through bubble G between electrode 32 c and the body fluid F.

Continued heating of body fluid F causes gas/steam bubble G to further expand. Eventually the size of bubble G is large enough to increase the distance between electrode 22 and fluid F to be great enough that the potential between them is insufficient to sustain the plasma and to continue the sparking across the bubble G. Thus, the plasma between electrodes 22 and 32 c dies, causing sparking to discontinue and causing the current to divert to electrodes 32 a, 32 b into body tissue T, causing ablation to occur. See FIG. 5C. A gas/steam insulating layer L will eventually form in the region surrounding the electrodes 32 a, 32 b. By this time, gas/steam bubble G around electrode 32 c may have dissipated, and the high resistance of the layer L will cause the current to divert once again into body fluid F via electrode 32 c rather than through electrodes 32 a, 32 b. This process may repeat many times during the ablation procedure.

A second embodiment of an ablation device 110 is shown in FIGS. 6A and 6B. The second embodiment operates in a manner similar to the first embodiment, but it includes structural features that allow the threshold voltage of the argon to be pre-selected. Certain body tissues require higher voltages in order for ablation to be achieved. This embodiment allows the user to select the desired ablation voltage and to have the system prevent current conduction until the pre-selected voltages are reached. Thus, there is no passage of current to the tissue until the desired ablation voltage is reached, and so there is no unnecessary resistive tissue heating during the rise-time of the voltage.

As discussed previously, the voltage threshold of the argon varies with the argon pressure in reservoir 120 and with the distance d across the spark gap, which in this embodiment is the distance extending between electrode 122 and ablation electrodes 132 a-132 c. The second embodiment allows the argon pressure and/or the distance d to be varied so as to allow the voltage threshold of the argon to be pre-selected to be equivalent to the desired ablation voltage for the target tissue. In other words, if a treatment voltage of 200V is desired, the user can configure the second embodiment such that that voltage will be the threshold voltage for the argon. Treatment voltages in the range of 50V to 10,000V, and most preferably 200V-500V, may be utilized.

Referring to FIG. 6A, device 110 includes a housing 112 formed of an insulating material such as glass, ceramic, siliciumoxid, PTFE or other high melting temperature material. A reservoir 120 housing a volume of argon gas is located in the housing's distal tip. A plunger 121 is disposed within the housing 112 and includes a wall 123. The plunger is moveable to move the wall proximally and distally between positions 121A and 121B to change the volume of reservoir 120. Plunger wall 123 is sealable against the interior wall of housing 112 so as to prevent leakage of the argon gas.

An elongate rod 126 extends through an opening (not shown) in plunger wall 123 and is fixed to the wall 123 such that the rod and wall can move as a single component. Rod 126 extends to the proximal end of the device 110 and thus may serve as the handle used to move the plunger 121 during use.

Internal electrode 122 is positioned within the reservoir 120 and is mounted to the distal end of rod 126 such that movement of the plunger 121 results in corresponding movement of the electrode 122. Electrode 122 is electrically coupled to a conductor 124 that extends through rod 126 and that is electrically coupled to RF generator 128. Rod 126 preferably serves as the insulator for conductor 124 and as such should be formed of an insulating material.

A return electrode 130 is disposed on the exterior surface of the housing 112 and is also electrically coupled to RF generator 128. A plurality of ablation electrodes 132 a, 132 b etc. are positioned on the distal end of the housing 112.

Operation of the embodiment of FIGS. 6A-6B is similar to that described with respect to FIGS. 5A-5B, and so most of that description will not be repeated. Operation differs in that use of the second embodiment includes the preliminary step of moving rod 126 proximally or distally to place plunger wall 123 and electrode 122 into positions that will yield a desired voltage threshold for the argon gas. Moving the plunger in a distal direction (towards the electrodes 132 a-132 c) will decrease the volume of the reservoir and accordingly will increase the pressure of the argon within the reservoir and vice versa. Increases in argon pressure result in increased voltage threshold, while decreases in argon pressure result in decreased voltage threshold.

Moving the plunger 126 will also increase or decrease the distance d between electrode 122 and electrodes 132 a-132 c. Increases in the distance d increase the voltage threshold and vice versa.

The rod 126 preferably is marked with calibrations showing the voltage threshold that would be established using each position of the plunger. This will allow the user to move the rod 126 inwardly (to increase argon pressure but decrease distance d) or outwardly (to decrease argon pressure but increase distance d) to a position that will give a threshold voltage corresponding to the voltage desired to be applied to the tissue to be ablated. Because the argon will not ignite into a plasma until the threshold voltage is reached, current will not flow to the electrodes 132 a, 132 b etc. until the pre-selected threshold voltage is reached. Thus, there is no unnecessary resistive tissue heating during the rise-time of the voltage.

Alternatively, the FIG. 6A embodiment may be configured such that plunger 121 and rod 126 may be moved independently of one another, so that argon pressure and the distance d may be adjusted independently of one another. Thus, if an increase in voltage threshold is desired, plunger wall 123 may be moved distally to increase argon pressure, or rod 126 may be moved proximally to increase the separation distance between electrode 122 and 132 a-132 c. Likewise, a decrease in voltage threshold may be achieved by moving plunger wall 123 proximally to decrease argon pressure, or by moving rod 126 distally to decrease the separation distance d. If such a modification to the FIG. 6A was employed, a separate actuator would be attached to plunger 121 to allow the user to move the wall 123, and the plunger 126 would be slidable relative to the opening in the wall 123 through which it extends.

During use of the embodiment of FIGS. 6A and 6B, it may be desirable to maintain a constant argon pressure despite increases in temperature. As discussed in connection with the method of FIGS. 5A-5D, eventual increases in temperature and pressure cause the voltage needed to ignite the argon to increase above the voltage being applied by the RF generator, resulting in termination of conduction of the electrodes. In the FIG. 6A embodiment, the pressure of the argon can be maintained despite increases in temperature by withdrawing plunger 121 gradually as the argon temperature increases. By maintaining the argon pressure, the threshold voltage of the argon is also maintained, and so argon plasma will continue to conduct current to the electrodes 132 a, 132 b etc. This may be performed with or without moving the electrode 122. Alternatively, the position of electrode 122 may be changed during use so as to maintain a constant voltage threshold despite argon temperature increases.

FIGS. 7A and 7B show an alternative embodiment of an ablation device 210 that is similar to the device of FIGS. 6A and 6B. In this embodiment, argon is sealed within reservoir 220 by a wall 217. Rather than utilizing a plunger (such as plunger 121 in FIG. 6A) to change the volume of reservoir 220, the FIGS. 7A-7B embodiment utilizes bellows 221 formed into the sidewalls of housing 212. A pullwire 226 (which may double as the insulation for conductor 224) extends through internal electrode 222 and is anchored to the distal end of the housing 212. The bellows may be moved to the contracted position shown in FIG. 7A, the expanded position shown in FIG. 7B, or any intermediate position between them.

Pulling the pullwire 226 collapses the bellows into a contracted position as shown in FIG. 7A and increases the pressure of the argon within the reservoir 220. Advancing the pullwire 226 expands the bellows as shown in FIG. 7B, thereby decreasing the pressure of the argon. The pullwire and bellows may be used to pre-select the threshold voltage, since (for a given temperature) increasing the argon pressure increases the threshold voltage of the argon and vice versa. Once the threshold voltage has been pre-set, operation is similar to that of the previous embodiments. It should be noted that in the third embodiment, the distance between electrode 222 and ablation electrodes 232 a-c remains fixed, although the device may be modified to allow the user to adjust this distance and to provide an additional mechanism for adjusting the voltage threshold of the device.

An added advantage of the embodiment of FIG. 7A is that the device may be configured to permit the bellows 221 to expand in response to increased argon pressure within the reservoir. This will maintain the argon pressure, and thus the threshold voltage of the argon, at a fairly constant level despite temperature increases within reservoir 220. Thus, argon plasma will continue to conduct current to the electrodes 132 a 132 b etc and ablation may be continued, as it will be a longer period of time until the threshold voltage of the argon exceeds the voltage applied by the RF generator.

FIGS. 8A through 13B are a series of embodiments that also utilize argon, but that maintain a fixed reservoir volume for the argon. In each of these embodiments, current is conducted from an internal electrode within the argon reservoir to external ablation electrodes once the voltage of the internal electrode reaches the threshold voltage of the argon gas.

Referring to FIGS. 8A and 8B, the fourth embodiment of an ablation device utilizes a housing 312 formed of insulating material, overlaying a conductive member 314. Housing 312 includes exposed regions 332 in which the insulating material is removed to expose the underlying conductive member 314. An enclosed reservoir 320 within the housing 212 contains argon gas, and an RF electrode member 322 is positioned within the reservoir. A return electrode (not shown) is attached to the patient. The fourth embodiment operates in the manner described with respect to FIGS. 5A-5D, except that the current returns to the RF generator via the return electrode on the patient's body rather than via one on the device itself.

The fifth embodiment shown in FIGS. 9A and 9B is similar in structure and operation to the fourth embodiment. A conductive member 414 is positioned beneath insulated housing 412, and openings in the housing expose electrode regions 432 of the conductive member 414. The fifth embodiment differs from the fourth embodiment in that it is a bipolar device having a return electrode 430 formed over the insulated housing 412. Return electrode 430 is coupled to the RF generator and is cutaway in the same regions in which housing 412 is cutaway; so as to expose the underlying conductor.

Internal electrode 422 is disposed within argon gas reservoir 420. During use, electrode regions 432 are placed into contact with body tissue to be ablated. The RF generator is switched on and begins to build the voltage of electrode 422 relative to ablation electrode regions 432. As with the previous embodiments, conduction of ablation energy from electrode 422 to electrode regions 432 will only begin once electrode 422 reaches the voltage threshold at which the argon in reservoir 420 ignites to form a plasma. Current passes through the tissue undergoing ablation and to the return electrode 430 on the device exterior.

The sixth embodiment shown in FIG. 10 is similar in structure and operation to the fifth embodiment, and thus includes a conductive member 514, an insulated housing 512 over the conductive member 512 and having openings to expose regions 532 of the conductive member. A return electrode 530 is formed over the housing 512, and an internal electrode 522 is positioned within a reservoir 520 containing a fixed volume of argon. The sixth embodiment differs from the fifth embodiment in that the exposed regions 532 of the conductive member 514 protrude through the housing 512 as shown. This is beneficial in that it improves contact between the exposed regions 532 and the target body tissue.

A seventh embodiment is shown in FIGS. 11A through 11C. As with the sixth embodiment, this embodiment includes an insulated housing 612 (such as a heat resistant glass or ceramic) formed over a conductive member 614, and openings in the insulated housing 612 to expose elevated electrode regions 632 of the conductive member 614. A return electrode 630 is formed over the housing 612. An internal electrode 622 is positioned within a reservoir 620 containing a fixed volume of argon.

The seventh embodiment differs from the sixth embodiment in that there is an annular gap 633 between the insulated housing 612 and the elevated regions 632 of the conductive member 614. Annular gap 633 is fluidly coupled to a source of suction and/or to an irrigation supply. During use, suction may be applied via gap 633 to remove ablation byproducts (e.g. tissue and other debris) and/or to improve electrode contact by drawing tissue into the annular regions between electrode regions 632 and ground electrode 630. An irrigation gas or fluid may also be introduced via gap 633 during use so as to flush ablation byproducts from the device and to cool the ablation tip and the body tissue. Conductive or non-conductive fluid may be utilized periodically during the ablation procedure to flush the system.

Annular gap 633 may also be used to deliver argon gas into contact with the electrodes 632. When the voltage of the electrode regions 632 reaches the threshold of argon delivered through the gap 633, the resulting argon plasma will conduct from electrode regions 632 to the ground electrode 630, causing lateral sparking between the electrodes 632, 630. The resulting sparks create an “electrical file” which cuts the surrounding body tissue.

An eighth embodiment of an ablation device is shown in FIGS. 12A and 12B. This device 710 is similar to the device of the fifth embodiment, FIGS. 9A and 9B, in a number of ways. In particular, device 710 includes a conductive member 714 positioned beneath insulated housing 712, and openings in the housing which expose electrode regions 732 of the conductive member 714. A return electrode 730 is formed over the insulated housing 712. Internal electrode 722 is disposed within an argon gas reservoir 720 having a fixed volume.

The eighth embodiment additionally includes a pair of telescoping tubular jackets 740, 742. Inner jacket 740 has a lower insulating surface 744 and an upper conductive surface 746 that serves as a second return electrode. Inner jacket 740 is longitudinally slidable between proximal position 740A and distal position 740B.

Outer jacket 742 is formed of insulating material and is slidable longitudinally between position 742A and distal position 742B.

A first annular gap 748 is formed beneath inner jacket 740 and a second annular gap 750 is formed between the inner and outer jackets 740, 742. These gaps may be used to deliver suction or irrigation to the ablation site to remove ablation byproducts.

The eighth embodiment may be used in a variety of ways. As a first example, jackets 740, 742 may be moved distally to expose less than all of tip electrode assembly (i.e. the region at which the conductive regions 732 are located). This allows the user to expose only enough of the conductive regions 732 as is needed to cover the area to be ablated within the body.

Secondly, in the event bleeding occurs at the ablation site, return electrode surface 730 may be used as a large surface area coagulation electrode, with return electrode surface 746 serving as the return electrode, so as to coagulate the tissue and to thus stop the bleeding. Outer jacket 742 may be moved proximally or distally to increase or decrease the surface area of electrode 746. Moving it proximally has the effect of reducing the energy density at the return electrode 746, allowing power to be increased to carry out the coagulation without increasing thermal treatment effects at return electrode 746.

Alternatively, in the event coagulation and/or is needed, electrode 730 may be used for surface coagulation in combination with a return patch placed into contact with the patient.

FIGS. 13A-13B show a ninth embodiment of an ablation device utilizing principles of the present invention. The ninth embodiment includes an insulated housing 812 having an argon gas reservoir 820 of fixed volume. A plurality of ablation electrodes 832 are embedded in the walls of the housing 812 such that they are exposed to the argon in reservoir 832 and exposed on the exterior of the device for contact with body tissue. A return electrode 830 is formed over the housing 812, but includes openings through which the electrodes 832 extend. An annular gap 833 lies between return electrode 830 and housing 812. As with previous embodiments, suction and/or irrigation may be provided through the gap 833. Additionally, argon gas may be introduced through the annular gap 833 and into contact with the electrodes 832 and body tissue so as to allow argon gas ablation to be performed.

An internal electrode 822 is positioned within reservoir 820. Electrode 822 is asymmetrical in shape, having a curved surface 822 a forming an arc of a circle and a pair of straight surfaces 822 b forming radii of the circle. As a result of its shape, the curved surface of the electrode 820 is always closer to the electrodes 832 than the straight surfaces. Naturally, other shapes that achieve this effect may alternatively be utilized.

Electrode 822 is rotatable about a longitudinal axis and can also be moved longitudinally as indicated by arrows in FIGS. 13A and 13B. Rotation and longitudinal movement can be carried out simultaneously or separately. This allows the user to selectively position the surface 822 a in proximity to a select group of the electrodes 832. For example, referring to FIGS. 13A and 13B, when electrode 822 is positioned as shown, curved surface 822 a is near electrodes 832 a, whereas no part of the electrode 822 is close to the other groups of electrodes 832 b-832 d.

As discussed earlier, the voltage threshold required to cause conduction between internal electrode 822 and ablation electrodes 832 will decrease with a decrease in distance between the electrodes. Thus, there will be a lower threshold voltage between electrode 822 and the ablation electrodes (e.g. electrode 832 a) adjacent to surface 822 a than there is between the electrode 822 and ablation electrodes that are farther away (e.g. electrodes 832 b-d. The dimensions of the electrode 822 and the voltage applied to electrode 822 are such that a plasma can only be established between the surface 822 a and the electrodes it is close to. Thus, for example, when surface 822 a is adjacent to electrodes 832 a as shown in the drawings, the voltage threshold between the electrodes 822 a and 832 a is low enough that the voltage applied to electrode 822 will cause plasma conduction to electrodes 832 a. However, the threshold between electrode 822 and the other electrodes 832 b-d will remain above the voltage applied to electrode 822, and so there will be no conduction to those electrodes.

This embodiment thus allows the user to selectively ablate regions of tissue by positioning the electrode surface 822 a close to electrodes in contact with the regions at which ablation is desired.

FIG. 14A shows a tenth embodiment of an ablation device utilizing voltage threshold principles. The tenth embodiment includes a housing 912 having a sealed distal end containing argon. Ablation electrodes 932 a-c are positioned on the exterior of the housing 912. An internal electrode 22 is disposed in the sealed distal end. Positioned between the internal electrode 922 and the electrodes 932 a-c is a conductive grid 933.

When electrode 922 is energized, there will be no conduction from electrode 922 to electrodes 932 a-c until the potential between electrode 922 and the body tissue/fluid in contact with electrodes 932 a-c reaches an initiating threshold voltage at which the argon gas will form a conductive plasma. The exact initiating threshold voltage is dependent on the argon pressure, its flowrate (if it is circulating within the device), and the distance between electrode 922 and the tissue/body fluid in contact with the ablation electrodes 932 a-c.

Because the RF generator voltage output varies sinusoidally with time, there are phases along the RF generator output cycle at which the RF generator voltage will drop below the voltage threshold. However, once the plasma has been ignited, the presence of energized plasma ions in the argon will maintain conduction even after the potential between electrode 922 and the body fluid/tissue has been fallen below the initiating threshold voltage. In other words, there is a threshold sustaining voltage that is below the initiating threshold voltage, but that will sustain plasma conduction.

In the embodiment of FIG. 14A, the grid 933 is spaced from the electrodes 932 a-c by a distance at which the corresponding plasma ignition threshold is a suitable ablation voltage for the application to which the ablation device is to be used. Moreover, the electrode 922 is positioned such that once the plasma is ignited, grid 933 may be deactivated and electrode 922 will continue to maintain a potential equal to or above the sustaining voltage for the plasma. Thus, during use, both grid 933 and electrode 922 are initially activated for plasma formation. Once the potential between grid 933 and body tissue/fluid reaches the threshold voltage and the plasma ignites, grid 933 will be deactivated. Because ions are present in the plasma at this point, conduction will continue at the sustaining threshold voltage provided by electrode 922.

The ability of ionized gas molecules in the argon to sustain conduction even after the potential applied to the internal electrode has fallen below the initiating threshold voltage can be undesirable. As discussed, an important aspect of voltage threshold ablation is that it allows for high voltage/low current ablation. Using the embodiments described herein, a voltage considered desirable for the application is selected as the threshold voltage. Because the ablation electrodes are prevented from conducting when the voltage delivered by the RF generator is below the threshold voltage, there is no conduction to the ablation electrode during the rise time from 0V to the voltage threshold. Thus, there is no resistive heating of the tissue during the period in which the RF generator voltage is rising towards the threshold voltage.

Under ideal circumstances, conduction would discontinue during the periods in which the RF generator voltage is below the threshold. However, since ionized gas remains in the argon reservoir, conduction can continue at voltages below the threshold voltage. Referring to FIG. 4A, this results in the sloping trailing edge of the ablation voltage waveform, which approximates the trailing portion of the sinusoidal waveform produced by the RF generator (FIG. 3). This low-voltage conduction to the tissue causes resistive heating of the tissue when only high voltage ablation is desired.

The grid embodiment of FIG. 14A may be used to counter the effect of continued conduction so as to minimize collateral damage resulting from tissue heating. During use of the grid embodiment, the trailing edge of the ablation voltage waveform is straightened by reversing the polarity of grid electrode 933 after the RF generator has reached its peak voltage. This results in formation of a reverse field within the argon, which prevents the plasma flow of ions within the argon gas and that thus greatly reduces conduction. This steepens the slop of the trailing edge of the ablation potential waveform, causing a more rapid drop towards 0V, such that it approximates the waveform shown in FIG. 4B.

FIGS. 15A and 15B show an eleventh embodiment utilizing principles of the present invention. As with the tenth embodiment, the eleventh embodiment is advantageous in that it utilizes a mechanism for steepening the trailing edge of the ablation waveform, thus minimizing conduction during periods when the voltage is below the threshold voltage. In the eleventh embodiment, this is accomplished by circulating the argon gas through the device so as to continuously flush a portion of the ionized gas molecules away from the ablation electrodes.

The eleventh embodiment includes a housing 1012 having an ablation electrodes 1032. An internal electrode 1022 is positioned within the housing 1012 and is preferably formed of conductive hypotube having insulation 1033 formed over all but the distal-most region. A fluid lumen 1035 is formed in the hypotube and provides the conduit through which argon flows into the distal region of housing 1012. Flowing argon exits the housing through the lumen in the housing 1012, as indicated by arrows in FIG. 15A. A pump 1031 drives the argon flow through the housing.

It should be noted that different gases will have different threshold voltages when used under identical conditions. Thus, during use of the present invention the user may select a gas for the spark gap switch that will have a desired threshold voltage. A single type of gas (e.g. argon) may be circulated through the system, or a plurality of gases from sources 1033 a-c may be mixed by a mixer pump 1031 a as shown in FIG. 15C, for circulation through the system and through the spark gap switch 1035. Mixing of gases is desirable in that it allows a gas mixture to be created that has a threshold voltage corresponding to the desired treatment voltage. In all of the systems using circulated gas, gas leaving the system may be recycled through, and/or exhausted from, the system after it makes a pass through the spark gap switch.

FIGS. 16A through 16D schematically illustrate the effect of circulating the argon gas through the device of FIG. 15A. Circulation preferably is carried out at a rate of approximately 0.1 liters/minute to 0.8 liters/minute.

Referring to FIG. 16A, during initial activation of the RF generator, the potential between internal electrode 1022 and ablation electrode 1032 is insufficient to create an argon plasma. Argon molecules are thus non-ionized, and the voltage measured at the load L is 0V. There is no conduction from electrode 1022 to electrode 1032 at this time.

FIG. 16B shows the load voltage measured from internal electrode 1022 across the body fluid/tissue to return electrode 1030. Once the RF generator voltage output reaches voltage threshold V_(T) of the argon, argon molecules are ionized to create a plasma. A stream of the ionized molecules flows from electrode 1022 to electrode 1032 and current is conducted from electrode 1032 to the tissue. Because the argon is flowing, some of the ionized molecules are carried away. Nevertheless, because of the high voltage, the population of ionized molecules is increasing at this point, and more than compensates for those that flow away, causing an expanding plasma within the device.

After the RF generator voltage falls below V_(T), ion generation stops. Ionized molecules within the argon pool flow away as the argon is circulated, and others of the ions die off. Thus, the plasma begins collapsing and conduction to the ablation electrodes decreases and eventually stops. See FIGS. 16C and 16D. The process then repeats as the RF generator voltage approaches (−V_(T)) during the negative phase of its sinusoidal cycle.

Circulating the argon minimizes the number of ionized molecules that remain in the space between electrode 1022 and electrode 1032. If a high population of ionized molecules remained in this region of the device, their presence would result in conduction throughout the cycle, and the voltage at the tissue/fluid load L would eventually resemble the sinusoidal output of the RF generator. This continuous conduction at low voltages would result in collateral heating of the tissue.

Naturally, the speed with which ionized molecules are carried away increases with increased argon flow rate. For this reason, there will be more straightening of the trailing edge of the ablation waveform with higher argon flow rates than with lower argon flow rates. This is illustrated graphically in FIG. 17. The upper waveform shows the RF generator output voltage. The center waveform is the voltage output measured across the load (i.e. from the external electrode 1032 across the body tissue/fluid to the return electrode 1030) for a device in which the argon gas is slowly circulated. The lower waveform is the voltage output measured across the load for a device in which the argon gas is rapidly circulated. It is evident from the FIG. 17 graphs that the sloped trailing edge of the ablation waveform remains when the argon is circulated at a relatively low flow rate, whereas the trailing edge falls off more steeply when a relatively high flow rate is utilized. This steep trailing edge corresponds to minimized current conduction during low voltage phases. Flow rates that achieve the maximum benefit of straightening the trailing edge of the waveform are preferable. It should be noted that flow rates that are too high can interfere with conduction by flushing too many ionized molecules away during phases of the cycle when the output is at the threshold voltage. Optimal flow rates will depend on other physical characteristics of the device, such as the spark gap distance and electrode arrangement.

It should also be noted that the distance between internal electrode 1022 and external electrode 1032 also has an effect on the trailing edge of the ablation potential waveform. In the graphs of FIG. 18, the RF generator output is shown in the upper graph. V_(PRFG) represents the peak voltage output of the RF generator, V_(T1) represents the voltage threshold of a device having a large separation distance (e.g. approximately 1 mm) between electrodes 1022 and 1032, and V_(T2) represents the voltage threshold of a device in which electrodes 1022, 1032 are closely spaced—e.g. by a distance of approximately 0.1 mm. As previously explained, there is a higher voltage threshold in a device with a larger separation distance between the electrodes. This is because there is a large population of argon molecules between the electrodes 1022, 1032 that must be stripped of electrons before plasma conduction will occur. Conversely, when the separation distance between electrodes 1022 and 1032 is small, there is a smaller population of argon molecules between them, and so less energy is needed to ionize the molecules to create plasma conduction.

When the RF generator output falls below the threshold voltage, the molecules begin to deionize. When there are fewer ionized molecules to begin with, as is the case in configurations having a small electrode separation distance, the load voltage is more sensitive to the deionization of molecules, and so the trailing edge of the output waveform falls steeply during this phase of the cycle.

For applications in which a low voltage threshold is desirable, the device may be configured to have a small electrode spacing (e.g. in the range of 0.001-5 mm, most preferably 0.05-0.5 mm) and non-circulating argon. As discussed, doing so can produce a load output waveform having a steep rising edge and a steep falling edge, both of which are desirable characteristics. If a higher voltage threshold is needed, circulating the argon in a device with close inter-electrode spacing will increase the voltage threshold by increasing the pressure of the argon. This will yield a highly dense population of charged ions during the phase of the cycle when the RF generator voltage is above the threshold voltage, but the high flow rate will quickly wash many ions away, causing a steep decline in the output waveform during the phases of the cycle when the RF generator voltage is below the threshold.

A twelfth embodiment of a system utilizing principles of the present invention is shown schematically in FIG. 19. The twelfth embodiment allows the threshold voltage to be adjusted by permitting the spark gap spacing (i.e. the effective spacing between the internal electrode and the ablation electrode) to be selected. It utilizes a gas-filled spark gap switch 1135 having a plurality of internal spark gap electrodes 1122 a, 1122 b, 1122 c. Each internal electrode is spaced from ablation electrode 1132 by a different distance, D1, D2, D3, respectively. An adjustment switch 1125 allows the user to select which of the internal electrodes 1122 a, 1122 b, 1122 c to utilize during a procedure. Since the threshold voltage of a spark gap switch will vary with the distance between the internal electrode and the contact electrode, the user will select an internal electrode, which will set the spark gap switch to have the desired threshold voltage. If a higher threshold voltage is used, electrode 1122 a will be utilized, so that the larger spark gap spacing D1 will give a higher threshold voltage. Conversely, the user will selected electrode 1122 c, with the smaller spark gap spacing, if a lower threshold voltage is needed.

It is useful to mention that while the spark gap switch has been primarily described as being positioned within the ablation device, it should be noted that spark gap switches may be positioned elsewhere within the system without departing with the scope of the present invention. For example, referring to FIG. 19, the spark gap switch 1135 may be configured such that the ablation electrode 1132 disposed within the spark gap is the remote proximal end of a conductive wire that is electrically coupled to the actual patient contact portion of the ablation electrode positioned into contact with body tissue. A spark gap switch of this type may be located in the RF generator, in the handle of the ablation device, or in the conductors extending between the RF generator and the ablation device.

FIGS. 20-26 illustrate additional embodiments of a surgical probe that utilizes voltage threshold means for controlling ablative energy delivery to tissue at a targeted site. In general, FIG. 20 depicts an exemplary probe 1200 with handle portion 1202 coupled to extension member 1204 that supports working end 1205. The working end 1205 can have any suitable geometry and orientation relative to axis 1208 and is shown as an axially-extending end for convenience. A hand-held probe 1200 as in FIG. 20 can be used to move or paint across tissue to ablate the tissue surface, whether in an endoscopic treatment within a fluid as in arthroscopy, or in a surface tissue treatment in air. In this embodiment, the exterior sheath 1206 is an insulator material (FIG. 21) and the probe is adapted to function in a mono-polar manner by cooperating with a ground pad 1208 coupled to the targeted tissue TT (see FIGS. 20 and 21). The system also can operate in a bi-polar manner by which is meant the working end itself carries a return electrode, as will be illustrated in FIG. 26 below.

Referring to FIGS. 20 and 21, the working end 1205 comprises a microporous ceramic body 1210 that cooperates with an interior voltage threshold mechanism or spark gap switch as described above. In one embodiment in FIG. 21, the ceramic body 1210 has interior chamber 1215 that receives a flowable, ionizable gas that flows from a pressurized gas source 1220 and is extracted by a negative pressure source 1225. In this embodiment, it can be seen that gas flows through interior lumen 1228 in conductive sleeve 1230. The gas is then extracted through concentric lumen 1235 that communicates with negative pressure source 1225 as indicated by the gas flow arrows F in FIG. 21. Any suitable spacer elements 1236 (phantom view) can support the conductive sleeve 1230 within the probe body to maintain the arrangement of components to provide the gas inflow and outflow pathways. As can be seen in FIG. 21, the conductive sleeve 1230 is coupled by electrical lead 1238 to electrical source 1240 to allow its function and as electrode component with the distal termination 1241 of sleeve 1230 on one side of a spark gap indicated at SG.

The interior surface 1242 of ceramic body 1210 carries an interior electrode 1244A at the interior of the microporous ceramic. As can be seen in enlarged cut-away view of FIG. 22, the ceramic has a microporous working surface 1245 wherein a micropore network 1248 extends through the thickness TH of the ceramic body surface overlying the interior electrode 1244A. The sectional view of FIG. 21 illustrates the pore network 1248 extending from working surface 1245 to the interior electrode 1244A. The function of the pore network 1248 is to provide a generally defined volume or dimension of a gas within a plurality of pores or pathways between interior electrode 1244A and the targeted tissue site TT. Of particular importance, the cross-sectional dimensions of the pores is selected to insure that the pores remain free of fluid ingress in normal operating pressures of an underwater surgery (e.g., arthroscopy) or even moisture ingress in other surgeries in a normal air environment. It has been found that the mean pore cross-section of less than about 10 microns provides a suitable working surface 1245 for tissue ablation; and more preferably a mean pore cross-section of less than about 5 microns. Still more preferably, the mean pore cross-section is less than about 1 micron. In any event, the microporous ceramic allows for electrical energy coupling across and through the pore network 1248 between the interior electrode 1244A and the targeted tissue site TT, but at the same time the microporous ceramic is impervious to liquid migration therein under pressures of a normal operating environment. This liquid-impervious property insures that electrical energy will ablatively arc through the pore network 1248 rather than coupling with water or moisture within the pore network during operation.

In FIG. 21, it also can be seen that working surface 1245 is defined as a limited surface region of the ceramic that is microporous. The working end 1205 has a ceramic glaze 1250 that covers the exterior of the ceramic body except for the active working surface 1245. Referring now to FIG. 22, the thickness TH of the microporous ceramic body also is important for controlling the ablative energy-tissue interaction. The thickness TH of the ceramic working surface can range from as little as about 5 microns to as much as about 1000 microns. More preferably, the thickness TH is from about 50 microns to 500 microns.

The microporous ceramic body 1210 of FIGS. 20-22 can be fabricated of any suitable ceramic in which the fabrication process can produce a hard ceramic with structural integrity that has substantially uniform dimension, interconnected pores extending about a network of the body—with the mean pore dimensions described above. Many types of microporous ceramics have been developed for gas filtering industry and the fabrication processed can be the same for the ceramic body of the invention. It has been found that a ceramic of about 90%-98% alumina that is fired for an appropriate time and temperature can produce the pore network 1248 and working surface thickness TH required for the ceramic body to practice the method the invention. Ceramic micromolding techniques can be used to fabricate the net shape ceramic body as depicted in FIG. 21.

In FIGS. 21 and 22, it can be understood how the spark gap SG (not-to-scale) between conductor sleeve 1230 and the interior electrode 1244A can function to provide cycle-to-cycle control of voltage applied to the electrode 1244A and thus to the targeted treatment site to ablate tissue. As can be understood in FIG. 22, a gas flow F of a gas (e.g., argon) flows through the interior of the ceramic body to flush ionized gases therefrom to insure that voltage threshold mechanism functions optimally, as described above.

FIG. 23 illustrates another embodiment of working end that included multiple conductor sleeves portions 1230 and 1230′ that are spaced apart by insulator 1252 and define different gap dimensions from distal surface 1241 and 1241′ to interior electrode 1244A. It can be understood that the multiple conductor sleeves portions 1230 and 1230′, that can range from 2 to 5 or more, can be selected by controller 1255 to allow a change in the selected dimension of the spark gap indicated at SG and SG′. The dimension of the spark gap will change the voltage threshold to thereby change the parameter of ablative energy applied to the targeted tissue, which can be understood from the above detailed description.

FIG. 24 illustrates a greatly enlarged cut-away view of an alternative microporous ceramic body 1210 wherein the interior electrode 1244B also is microporous to cooperate with the microporous ceramic body 1210 in optimizing electrical energy application across and through the pore network 1248. In this embodiment, the spark gap again is indicated at SG and defines the dimension between distal termination 1241 of conductor sleeve 1230 and the electrode 1244B. The porous electrode 1244B can be any thin film with ordered or random porosities fabricated therein and then bonded or adhered to ceramic body 1210. The porous electrode also can be a porous metal that is known in the art. Alternatively, the porous electrode 1224B can be vapor deposited on the porous surface of the ceramic body. Still another alternative that falls within the scope of the invention is a ceramic-metal composite material that can be formed to cooperate with the microporous ceramic body 1210.

FIG. 24 again illustrates that a gas flow indicated by arrows F will flush ionized gases from the interior of the ceramic body 1210. At the same time, however, the pores 1258 in electrode 1244B allow a gas flow indicated at F′ to propagate through pore network 1248 in the ceramic body to exit the working surface 1245. This gas flow F′ thus can continuously flush the ionized gases from the pore network 1248 to insure that arc-like electrical energy will be applied to tissue from interior electrode 1244B through the pore network 1248—rather than having electrical energy coupled to tissue through ionized gases captured and still resident in the pore network from a previous cycle of energy application. It can be understood that the percentage of total gas flow F that cycles through interior chamber 1215 and the percentage of gas flow GF′ that exits through the pore network 1248 can be optimized by adjusting (i) the dimensions of pores 1258 in electrode 1244B; (ii) the mean pore dimension in the ceramic body 1210, the thickness of the ceramic working surface and mean pore length, (iv) inflow gas pressure; and (v) extraction pressure of the negative pressure source. A particular probe for a particular application thus will be designed, in part by modeling and experimentation, to determine the optimal pressures and geometries to deliver the desired ablative energy parameters through the working surface 1245. This optimization process is directed to provide flushing of ionized gas from the spark gap at the interior chamber 1215 of the probe, as well as to provide flushing of the micropore network 1248. In this embodiment, the micropore network 1248 can be considered to function as a secondary spark gap to apply energy from electrode 1224B to the targeted tissue site TT.

In another embodiment depicted in FIG. 25, it should be appreciated that the spark gap interior chamber 1215′ also can be further interior of the microporous ceramic working surface 1245. For example, FIG. 25 illustrates a microprobe working end 1260 wherein it may be impractical to circulate gas to a needle-dimension probe tip 1262. In this case, the interior chamber 1215′ can be located more proximally in a larger cross-section portion of the probe. The working end of FIG. 25 is similar to that of FIG. 21 in that gas flows F are not used to flush ionized gases from the pore network 1248.

FIG. 26 illustrates another embodiment of probe 1270 that has the same components as in FIGS. 22 and 24 for causing electrical energy delivery through an open pore network 1248 in a substantially thin microporous ceramic body 1210. In addition, the probe 1270 carries a return electrode 1275 at an exterior of the working end for providing a probe that functions in a manner generally described as a bi-polar energy delivery. In other words, the interior electrode 1244A or 1244B comprises a first polarity electrode (indicated at (+)) and the return electrode 1275 (indicated at (−)) about the exterior of the working end comprises a second polarity electrode. This differs from the embodiment of FIG. 21, for example, wherein the second polarity electrode is a ground pad indicated at 1208. The bi-polar probe 1270 that utilizes voltage threshold energy delivery through a microporous ceramic is useful for surgeries in a liquid environment, as in arthroscopy. It should be appreciated that the return electrode 1275 can be located in any location, or a plurality of locations, about the exterior of the working end and fall within the scope of the invention.

The probe 1270 of FIG. 26 further illustrates another feature that provided enhanced safety for surgical probe that utilizes voltage threshold energy delivery. The probe has a secondary or safety spark gap 1277 in a more proximal location spaced apart a selected dimension SD from the interior spark gap indicated at SG. The secondary spark gap 1277 also defines a selected dimension between the first and second polarity electrodes 1230 and 1275. As can be seen in FIG. 26, the secondary spark gap 1277 consists of an aperture in the ceramic body 1210 or other insulator that is disposed between the opposing polarity electrodes. In the event that the primary spark gap SG in the interior chamber 1215 is not functioning optimally during use, any extraordinary current flows can jump the secondary spark gap 1277 to complete the circuit. The dimension across the secondary spark gap 1277 is selected to insure that during normal operations, the secondary spark gap 1277 maintains a passive role without energy jumping through the gap.

FIGS. 27A and 27B illustrate another embodiment of electrosurgical ablation system 1400A and a method of use. The ablation system 1400A again comprises an elongated probe 1402 having a working end 1405 fabricated of a non-conductive ceramic body 1410. In this embodiment, the system includes a remote source 1420 of a liquid electrode 1422 that is adapted to provide a pressurized flow of the liquid electrode through a flow channel or pathway 1424 that extends through the probe body to an interior of working surface 1425 that is configured for engaging tissue. The flow channel has a first channel portion 1426 that has a first mean cross section. In the embodiment of FIGS. 27A and 27B, the working surface includes at least one flow restriction channel (or second reduced cross-section channel portion) indicated at 1428 for restricting the flow of liquid electrode 1422 therethrough, as will be described in more detail below. In this embodiment, the flow channel 1424 includes a return channel portion indicated at 1430 for returning the liquid electrode 1422 in a loop to an exterior of the probe to reservoir 1435 which optionally can be connected back to source 1420. The remote source 1420 of the liquid electrode 1422 further includes a pressurization mechanism which can be any suitable form of pump capable of providing a flow of the liquid electrode 1422 having a pressure ranging from about 1 psi to 1,000 psi.

The ablation system 1400A of FIGS. 27A and 27B further comprises an high frequency electrical source 1440 that includes electrode first and second electrode terminals 1442 and 1444 for coupling high frequency energy to flow of the liquid electrode 1422. As can be seen in FIG. 27A, the first electrode terminal 1442 comprises an electrically conductive member with first flow channel portion 1426 extending therethrough. In FIGS. 27A and 27B, the second electrode terminal 1444 comprises a ground pad or needle that is coupled to targeted tissue 1445 as is known in the art. The probe 1402 of FIGS. 27A and 27B can be any hand-held instrument as in FIG. 20 wherein a support member indicated at 1426 is configured for support of the working end 1405 and coupling to a handle.

Still referring to FIGS. 27A and 27B, the mean cross section of the flow restriction channel 1428 is less than about 1000 microns, and preferably less than about 500 microns or less than about 250 microns. The flow restriction channel 1428 can also comprise a plurality of flow restriction channels. The manner of using the flow restriction channel 1428 will be further described below, and another means of describing the invention encompasses a probe having a first interior channel portion 1426 with a first mean cross-section and a flow restricting channel portion 1428 with a lesser cross-section extending through the working surface 1425. In one embodiment, the flow restricting channel portion 1428 has a mean cross-section that is less than 50% of the first channel portion, or less than 20% of the first channel portion, or less than 10% of the first channel portion.

FIGS. 27A and 27B illustrate a manner of using the probe system 1400A to carry out a method of the invention for ablating a targeted tissue site 1445. As can be seen in FIG. 27A, the working surface 1425 and flow restriction channel 1428 are a small distance away from tissue 1445 and the liquid electrode 1422 will drip through flow restriction channel 1428. In FIG. 27B, the working surface 1425 and flow restriction channel 1428 are moved according to arrows to contact the targeted tissue 1445 which causes the liquid electrode flow to be further restricted while at the same time coupling the flow between the poles to thereby instantly create a plasma indicated at 1450 in and about the flow restriction channel 1428. The plasma is thus formed or enhanced when contact with the tissue is carried out which thereby ablates the tissue. Thus, the system can be designed to automatically actuate on tissue contact. The electrical energy parameters (voltage and current) are selected to insure that energy density in flow restriction channel 1428 will be sufficient to instantly convert the liquid electrode into a plasma upon the restriction of the flow. The tip or the probe or working surface 1425 then can be translated across targeted tissue to ablate a larger tissue region or to transect a tissue, for example in an endoscopic surgery. The system also can be used in a submerged or under-water surgery such as an arthroscopic surgery. In such an arthroscopic surgery, the irrigation fluid can be saline wherein the physician can use an on-off switch to control creation of the plasma 1450 as in FIG. 27B. It should be appreciated that the working end 1405 and working surface 1425 can have any suitable configuration such as a blunt tip, sharp tip or blade-like edge known in the art.

FIG. 28 illustrates and alternative probe system 1400B that is similar to that of FIGS. 27A-27B except that a return flow path 1430 for the liquid electrode is not provided. In this embodiment, it also can be seen that first electrode terminal 1442 for coupling with the flow of liquid electrode 1422 is more remote from the working end 1405 can be located remote from a handle of the probe (see FIG. 20).

FIG. 29 illustrates and alternative probe system 1400C that is similar to that of FIGS. 27A-27B and 28 except that the second electrode terminal 1444 comprises an exposed portion of probe member 1402 for an embodiment used in a submerged surgery. In FIG. 29, it can be seen that a liquid 1455 is provided, for example in an arthroscopic surgery.

FIG. 30 illustrates and alternative probe system 1400D that is similar to that of FIGS. 28 and 29 except that the first electrode terminal 1442 comprises a voltage threshold assembly 1460 as described in 12B and FIGS. 15A-15B above. In this embodiment, the entire voltage threshold assembly 1460 is within the flow channel 1424 for controlling the peak voltage applied to the flow of the liquid electrode 1422.

In another embodiment 1440E shown in FIG. 31 which is similar to that of FIG. 27A. In this embodiment, the working surface 1425 comprises at least one substantially linear flow restrictor channel 1428 in a porous ceramic body portion indicated at 1465. In using the embodiment of FIG. 31, the initial plasma is ignited in restriction channel 1428 as in FIGS. 27A-27B, and then the plasma propagates instantly to the porous ceramic body portion 465 to thereby create a greater plasma geometry for ablating tissue that contacts the working surface of the probe. In another embodiment (not shown) the working surface 1425 comprises a microporous ceramic alone similar to body portion 1465 of FIG. 31 that provides the flow restricting structure for enabling the formation of plasma. In this embodiment, the inter-connected flow channels through the porous ceramic will create a plasma therein for ablating tissue.

A method of the invention thus comprise providing a flow of a liquid electrode through a probe working surface adjacent to or in contact with targeted tissue, applying high frequency voltage to the liquid electrode flow, and restricting said flow through the working surface thereby causing formation of a plasma for ablation of tissue. The step of restricting the flow includes restricting the flow with a flow restriction structure in the probe working surface. Alternatively, the step of restricting the flow includes restricting the flow by contacting at least one opening in the working surface with targeted tissue.

Several embodiments of voltage threshold ablation systems, and methods of using them, have been described herein. It should be understood that these embodiments are described only by way of example and are not intended to limit the scope of the present invention. Modifications to these embodiments may be made without departing from the scope of the present invention, and features and steps described in connection with some of the embodiments may be combined with features described in others of the embodiments. Moreover, while the embodiments discuss the use of the devices and methods for tissue ablation, it should be appreciated that other electrosurgical procedures such as cutting and coagulation may be performed using the disclosed devices and methods. It is intended that the scope of the invention is to be construed by the language of the appended claims, rather than by the details of the disclosed embodiments. 

1. A method for ablation of tissue comprising: providing a flow of a liquid electrode through a probe working surface adjacent to or in contact with targeted tissue; applying high frequency voltage to the liquid electrode flow; and restricting said flow with a plurality of flow restriction channels through the working surface thereby causing formation of a plasma for ablation of tissue.
 2. The method of claim 1 wherein the restricting step includes restricting said flow with flow restriction channel(s) having a mean diameter of less than 1000 microns.
 3. The method of claim 1 wherein the restricting step includes restricting said flow with flow restriction channel(s) having a mean diameter of less than 500 microns.
 4. The method of claim 1 wherein the restricting step includes restricting said flow with flow restriction channel(s) having a mean diameter of less than 250 microns.
 5. The method of claim 1 wherein the providing step provides a pressurized flow of saline solution.
 6. The method of claim 1 wherein the providing step provides a pressurized flow of a hypertonic saline solution.
 7. A method for ablation of tissue comprising: providing a pressurized flow of a hypertonic saline through a probe working surface wherein the working surface is configured with at least one flow restricting channel; coupling sufficient electrical energy to the flow of the hypertonic saline liquid electrode wherein said flow restricting channel causes formation of a plasma thereabout, and contacting the working surface to targeted tissue wherein the plasma causes ablation of tissue.
 8. The method of claim 7 wherein the at least one flow restricting channel comprises a single flow pathway for creating a plasma therein.
 9. The method of claim 7 wherein the at least one flow restricting channel comprises a multiple flow pathways in a microporous material for creating a plasma therein.
 10. The method of claim 7 wherein the at least one flow restricting channel has a mean cross section across a principal axis of less than about 500 microns.
 11. The method of claim 7 wherein the at least one flow restricting channel has a mean cross section across a principal axis of less than about 250 microns.
 12. The method of claim 7 wherein contacting the working surface to targeted tissue is carried out in a liquid submerged surgical site.
 13. The method of claim 7 wherein contacting the working surface to targeted tissue is carried out in a non-submerged surgical site.
 14. The method of claim 7 wherein the step of coupling electrical energy is carried out by a first polarity electrical terminal coupled to the flow of the liquid electrode proximal to the at least one flow restricting channel and a second polarity electrical terminal comprising a ground pad.
 15. The method of claim 7 wherein the step of coupling electrical energy is carried out by a first polarity electrical terminal coupled to the flow of the liquid electrode proximal to the at least one flow restricting channel and a second polarity electrical terminal on a exterior of the probe.
 16. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway; a voltage source operatively coupled to the liquid electrode; and a flow restriction structure comprising a plurality of substantially linear flow channels in working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue.
 17. The surgical system of claim 16 wherein the flow channel(s) have a mean cross section across a principal axis of less than about 1000 microns.
 18. The surgical system of claim 16 wherein the flow channel(s) have a mean cross section across a principal axis of less than about 500 microns.
 19. The surgical system of claim 16 wherein the flow channel(s) have a mean cross section across a principal axis of less than about 250 microns.
 20. The surgical system of claim 16 wherein the liquid electrode comprises saline solution.
 21. The surgical system of claim 16 wherein the liquid electrode source carries a flow pressure ranging between about 1 psi and 1000 psi.
 22. The surgical system of claim 16 further including first and second polarity electrical terminals for coupled electrical energy to the flow of the liquid electrode.
 23. The surgical system of claim 22 wherein the first polarity electrical terminal includes an voltage threshold mechanism.
 24. The surgical system of claim 22 wherein the first polarity electrical terminal includes an interior spark gap.
 25. The surgical system of claim 22 wherein the first polarity electrical terminal is within the flow pathway remote from the probe body.
 26. The surgical system of claim 22 wherein the first polarity electrical terminal is within the flow pathway at an interior of the probe body spaced apart from the at least one flow restricting channel.
 27. The surgical system of claim 22 wherein the second polarity electrical terminal comprises a ground pad or needle.
 28. The surgical system of claim 22 wherein the second polarity electrical terminal is positioned on an exterior of the probe body spaced apart from the at least one flow restricting channel.
 29. A surgical probe for ablation of tissue comprising; an elongated probe body with an interior flow channel having a first interior channel portion having a first mean cross-section and a second channel portion extending through a distal working surface having a second smaller mean cross-section; a liquid electrode source for providing a flow through the interior flow channel wherein the liquid electrode provides selected electrical parameters, and wherein the second channel portion restricts flow to cause an energy density sufficient to create a plasma about the second channel portion for ablation of tissue.
 30. The surgical probe of claim 29 wherein the second channel portion has mean cross-section that is less than 50% of the first channel portion.
 31. The surgical probe of claim 29 wherein the second channel portion has mean cross-section that is less than 20% of the first channel portion.
 32. The surgical probe of claim 29 wherein the second channel portion has mean cross-section that is less than 10% of the first channel portion.
 33. A method for ablation of tissue comprising: providing a flow of a liquid electrode through a probe working surface adjacent to or in contact with targeted tissue; applying high frequency voltage to the liquid electrode flow; and restricting said flow through the working surface with at least one flow restriction channel having a mean diameter of less than 1000 micron thereby causing formation of a plasma for ablation of tissue.
 34. The method of claim 33 wherein the restricting step includes restricting said flow with at least one flow restriction channel having a mean diameter of less than 500 microns.
 35. The method of claim 33 wherein the providing step provides a pressurized flow of saline solution.
 36. A method for ablation of tissue comprising: providing a flow of a hypertonic saline through a probe working surface adjacent to or in contact with targeted tissue; applying high frequency voltage to the hypertonic saline flow; and restricting said flow through the working surface with a flow restriction structure in the working surface thereby causing formation of a plasma for ablation of tissue.
 37. The method of claim 36 wherein the restricting step includes restricting said flow with a plurality of flow restriction channels structure in the working surface.
 38. The method of claim 36 wherein the flow restriction structures comprises at least one flow restriction channel having a mean diameter of less than 1000 microns.
 39. The method of claim 38 wherein the at least one flow restriction channel has a mean diameter of less than 500 microns.
 40. A method for ablation of tissue comprising: providing a flow of a hypertonic saline through a probe working surface adjacent to or in contact with targeted tissue; applying high frequency voltage to the hypertonic saline flow; and restricting said flow through the working surface thereby causing formation of a plasma for ablation of tissue wherein the restricting step includes restricting said flow by contacting at least one opening in the working surface with targeted tissue.
 41. A method for ablation of tissue comprising: providing a pressurized flow of a liquid electrode through a probe working surface wherein the working surface is configured with at least one flow restricting channel comprising a single flow pathway for creating a plasma therein; coupling sufficient electrical energy to the flow of the liquid electrode wherein said flow restricting channel comprising a single flow pathway therein causes formation of a plasma thereabout, and contacting the working surface to targeted tissue wherein the plasma causes ablation of tissue.
 42. A method for ablation of tissue comprising: providing a pressurized flow of a liquid electrode through a probe working surface wherein the working surface is configured with at least one flow restricting channel; coupling sufficient electrical energy to the flow of the liquid electrode wherein said flow restricting channel causes formation of a plasma thereabout; and contacting the working surface to targeted tissue in a non-submerged surgical site wherein the plasma causes ablation of tissue.
 43. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway; a voltage source operatively coupled to the liquid electrode; and a flow restriction structure comprising a plurality of substantially linear flow channels in a working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue.
 44. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway; a voltage source operatively coupled to the liquid electrode; and a flow restriction structure comprising a microporous structure in a ceramic working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue.
 45. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway; a voltage source operatively coupled to the liquid electrode; and a flow restriction structure comprising at least one channel having a mean cross section across a principal axis of less than about 1000 microns in working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue.
 46. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway including a flow loop extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway, where in the liquid is able to return to the source through the flow loop; a voltage source operatively coupled to the liquid electrode; and a flow restriction structure in working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue.
 47. A surgical system for ablation of tissue comprising: an elongated probe body with a flow pathway extending therethrough to a distal working surface for contacting tissue; a liquid electrode source coupled to the flow pathway; a voltage source operatively coupled to the liquid electrode; first and second polarity electrical terminals for coupling electrical energy to the flow pathway of the liquid electrode wherein the first polarity electrical terminal includes an interior spark gap; and a flow restriction structure in working surface for restricting the flow of the liquid electrode to thereby cause sufficient energy density therein to create a plasma about the flow restriction structure for ablation of tissue. 